English

Invertible bases and root vectors for analytic matrix-valued functions

Commutative Algebra 2023-12-25 v4

Abstract

We revisit the concept of a minimal basis through the lens of the theory of modules over a commutative ring RR. We first review the conditions for the existence of a basis for submodules of RnR^n where RR is a B\'{e}zout domain. Then, we define the concept of invertible basis of a submodule of RnR^n and, when RR is an elementary divisor domain, we link it to the Main Theorem of [G. D. Forney Jr., SIAM J. Control 13, 493--520, 1975]. Over an elementary divisor domain, the submodules admitting an invertible basis are precisely the free pure submodules of RnR^n. As an application, we let ΩC\Omega \subseteq \mathbb{C} be either a connected compact set or a connected open set, and we specialize to R=AR=\mathcal{A}, the ring of functions that are analytic on Ω\Omega. We show that, for any matrix A(z)Am×nA(z) \in \mathcal{A}^{m \times n}, ker A(z)An\mathrm{ker} \ A(z) \cap \mathcal{A}^n is a free A\mathcal{A}-module and admits an invertible basis, or equivalently a basis that is full rank upon evaluation at any λΩ\lambda \in \Omega. Finally, given λΩ\lambda \in \Omega, we use invertible bases to define and study maximal sets of root vectors at λ\lambda for A(z)A(z). This in particular allows us to define eigenvectors also for analytic matrices that do not have full column rank.

Keywords

Cite

@article{arxiv.2301.12955,
  title  = {Invertible bases and root vectors for analytic matrix-valued functions},
  author = {Vanni Noferini},
  journal= {arXiv preprint arXiv:2301.12955},
  year   = {2023}
}
R2 v1 2026-06-28T08:26:52.433Z